In-fiber second-harmonic generation with embedded two-dimensional materials

TL;DR

This paper demonstrates significant second-harmonic generation in silica optical fibers by embedding a monolayer of nonlinear MoS2, offering a scalable, efficient platform for chi(2)-based nonlinear fiber optics and photonics.

Contribution

The study introduces a scalable method to embed monolayer MoS2 into optical fibers, enabling efficient in-fiber second-harmonic generation without phase matching or ordered crystal growth.

Findings

Achieved over 1000x enhancement in SHG compared to reference samples.

Demonstrated a scalable CVD-based functionalization process.

Established a new platform for chi(2)-nonlinear fiber optics.

Abstract

Silica-based optical fibers are a workhorse of nonlinear optics. They have been used to demonstrate nonlinear phenomena such as solitons and self-phase modulation. Since the introduction of the photonic crystal fiber, they have found many exciting applications, such as supercontinuum white light sources and third-harmonic generation, among others. They stand out by their low loss, large interaction length, and the ability to engineer its dispersive properties, which compensate for the small chi(3) nonlinear coefficient. However, they have one fundamental limitation: due to the amorphous nature of silica, they do not exhibit second-order nonlinearity, except for minor contributions from surfaces. Here, we demonstrate significant second-harmonic generation in functionalized optical fibers with a monolayer of highly nonlinear MoS2 deposited on the fiber guiding core. The demonstration is carried out in a 3.5 mm short piece of exposed core fiber, which was functionalized in a scalable process CVD-based process, without a manual transfer step. This approach is scalable and can be generalized to other transition metal dichalcogenides and other waveguide systems. We achieve an enhancement of more than 1000x over a reference sample of equal length. Our simple proof-of-principle demonstration does not rely on either phase matching to fundamental modes, or ordered growth of monolayer crystals, suggesting that pathways for further improvement are within reach. Our results do not just demonstrate a new path towards efficient in-fiber SHG-sources, instead, they establish a platform with a new route to chi(2)-based nonlinear fiber optics, optoelectronics, and photonics platforms, integrated optical architectures, and active fiber networks.